Zoom optical system, optical apparatus, imaging apparatus and method for manufacturing the zoom optical system

ABSTRACT

A zoom optical system comprises, in order from an object: a front lens group (GFS) having a positive refractive power; an M1 lens group (GM 1 ) having a negative refractive power; an M2 lens group (GM 2 ) having a positive refractive power; and an RN lens group (GRN) having a negative refractive power, wherein upon zooming, distances between the front lens group and the M 1  lens group, between the M 1  lens group and the M 2  lens group, and between the M 2  lens group and the RN lens group change, upon focusing from an infinite distant object to a short distant object, the RN lens group moves, and the M 2  lens group comprises an A lens group that satisfies a following conditional expression, 1.10&lt;fvr/fTM2&lt;2.00, where, fvr: a focal length of the A lens group, and fTM2: a focal length of the M 2  lens group in a telephoto end state.

TECHNICAL FIELD

The present invention relates to a zoom optical system, an opticalapparatus and an imaging apparatus including the same, and a method formanufacturing the zoom optical system.

TECHNICAL BACKGROUND

Conventionally, zoom optical systems suitable for photographic cameras,electronic still cameras, video cameras and the like have been proposed(for example, see Patent literature 1).

PRIOR ARTS LIST Patent Document

Patent literature 1: Japanese Laid-Open Patent Publication No.H4-293007(A)

Unfortunately, according to the conventional zoom optical system,reduction in the weight of a focusing lens group is insufficient.

SUMMARY OF THE INVENTION

A zoom optical system according to the present invention comprises, inorder from an object: a front lens group having a positive refractivepower; an M1 lens group having a negative refractive power; an M2 lensgroup having a positive refractive power; and an RN lens group having anegative refractive power, wherein upon zooming, a distance between thefront lens group and the M1 lens group changes, a distance between theM1 lens group and the M2 lens group changes, and a distance between theM2 lens group and the RN lens group changes, upon focusing from aninfinite distant object to a short distant object, the RN lens groupmoves, and the M2 lens group comprises an A lens group that satisfies afollowing conditional expression,

1.10<fvr/fTM2<2.00

where

fvr: a focal length of the A lens group, and

fTM2: a focal length of the M2 lens group in a telephoto end state.

An optical apparatus according to the present invention comprises thezoom optical system.

An imaging apparatus according to the present invention comprises: thezoom optical system; and an imaging unit that takes an image formed bythe zoom optical system.

A method for manufacturing a zoom optical system according to thepresent invention is a method for manufacturing a zoom optical systemcomprising, in order from an object, a front lens group having apositive refractive power, an M1 lens group having a negative refractivepower, an M2 lens group having a positive refractive power, and an RNlens group having a negative refractive power, the method comprisingachieving an arrangement where upon zooming, a distance between thefront lens group and the M1 lens group changes, a distance between theM1 lens group and the M2 lens group changes, and a distance between theM2 lens group and the RN lens group changes, wherein upon focusing froman infinite distant object to a short distant object, the RN lens groupmoves, and the M2 lens group comprises an A lens group that satisfies afollowing conditional expression,

1.10<fvr/fTM2<2.00

where

fvr: a focal length of the A lens group, and

fTM2: a focal length of the M2 lens group in a telephoto end state.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a lens configuration of a zoom optical system according toa first example of this embodiment;

FIG. 2A is graphs showing various aberrations of the zoom optical systemaccording to the first example upon focusing on infinity in thewide-angle end state, and FIG. 2B is graphs showing meridional lateralaberrations (coma aberrations) when blur correction is applied to arotational blur by 0.30°;

FIG. 3 is graphs showing various aberrations of the zoom optical systemaccording to the first example upon focusing on infinity in theintermediate focal length state;

FIG. 4A is graphs showing various aberrations of the zoom optical systemaccording to the first example upon focusing on infinity in thetelephoto end state, and FIG. 4B is graphs showing meridional lateralaberrations when blur correction is applied to a rotational blur by0.20°;

FIGS. 5A, 5B and 5C are graphs showing various aberrations of the zoomoptical system according to the first example upon focusing on a shortdistant object in the wide-angle end state, the intermediate focallength state, and the telephoto end state, respectively;

FIG. 6 shows a lens configuration of a zoom optical system according toa second example of this embodiment;

FIG. 7A is graphs showing various aberrations of the zoom optical systemaccording to the second example upon focusing on infinity in thewide-angle end state, and FIG. 7B is graphs showing meridional lateralaberrations when blur correction is applied to a rotational blur by0.30°;

FIG. 8 is graphs showing various aberrations of the zoom optical systemaccording to the second example upon focusing on infinity in theintermediate focal length state;

FIG. 9A is graphs showing various aberrations of the zoom optical systemaccording to the second example upon focusing on infinity in thetelephoto end state, and FIG. 9B is graphs showing meridional lateralaberrations when blur correction is applied to a rotational blur by0.20°;

FIGS. 10A, 10B and 10C are graphs showing various aberrations of thezoom optical system according to the second example upon focusing on ashort distant object in the wide-angle end state, the intermediate focallength state, and the telephoto end state, respectively;

FIG. 11 shows a lens configuration of a zoom optical system according toa third example of this embodiment;

FIG. 12A is graphs showing various aberrations of the zoom opticalsystem according to the third example upon focusing on infinity in thewide-angle end state, and FIG. 12B is graphs showing meridional lateralaberrations when blur correction is applied to a rotational blur by0.30°;

FIG. 13 is graphs showing various aberrations of the zoom optical systemaccording to the third example upon focusing on infinity in theintermediate focal length state;

FIG. 14A is graphs showing various aberrations of the zoom opticalsystem according to the third example upon focusing on infinity in thetelephoto end state, and FIG. 14B is graphs showing meridional lateralaberrations when blur correction is applied to a rotational blur by0.20°;

FIGS. 15A, 15B and 15C are graphs showing various aberrations of thezoom optical system according to the third example upon focusing on ashort distant object in the wide-angle end state, the intermediate focallength state, and the telephoto end state, respectively;

FIG. 16 shows a lens configuration of a zoom optical system according toa fourth example of this embodiment;

FIG. 17A is graphs showing various aberrations of the zoom opticalsystem according to the fourth example upon focusing on infinity in thewide-angle end state, and FIG. 17B is graphs showing meridional lateralaberrations when blur correction is applied to a rotational blur by0.30°;

FIG. 18 is graphs showing various aberrations of the zoom optical systemaccording to the fourth example upon focusing on infinity in theintermediate focal length state;

FIG. 19A is graphs showing various aberrations of the zoom opticalsystem according to the fourth example upon focusing on infinity in thetelephoto end state, and FIG. 19B is graphs showing meridional lateralaberrations when blur correction is applied to a rotational blur by0.20°;

FIGS. 20A, 20B and 20C are graphs showing various aberrations of thezoom optical system according to the fourth example upon focusing on ashort distant object in the wide-angle end state, the intermediate focallength state, and the telephoto end state, respectively;

FIG. 21 shows a lens configuration of a zoom optical system according toa fifth example of this embodiment;

FIG. 22A is graphs showing various aberrations of the zoom opticalsystem according to the fifth example upon focusing on infinity in thewide-angle end state, and FIG. 22B is graphs showing meridional lateralaberrations when blur correction is applied to a rotational blur by0.30°;

FIG. 23 is graphs showing various aberrations of the zoom optical systemaccording to the fifth example upon focusing on infinity in theintermediate focal length state;

FIG. 24A is graphs showing various aberrations of the zoom opticalsystem according to the fifth example upon focusing on infinity in thetelephoto end state, and FIG. 24B is graphs showing meridional lateralaberrations when blur correction is applied to a rotational blur by0.20°;

FIGS. 25A, 25B and 25C are graphs showing various aberrations of thezoom optical system according to the fifth example upon focusing on ashort distant object in the wide-angle end state, the intermediate focallength state, and the telephoto end state, respectively;

FIG. 26 shows a configuration of a camera comprising a zoom opticalsystem according to this embodiment; and

FIG. 27 is a flowchart showing a method for manufacturing the zoomoptical system according to this embodiment.

DESCRIPTION OF THE EMBODIMENTS

Hereinafter, a zoom optical system, an optical apparatus, and an imagingapparatus of this embodiment are described with reference to thedrawings. As shown in FIG. 1 , a zoom optical system ZL(1) that is anexample of a zoom optical system (zoom lens) ZL according to thisembodiment comprises, in order from an object: a front lens group GFShaving a positive refractive power; an M1 lens group GM1 having anegative refractive power; an M2 lens group GM2 having a positiverefractive power; and an RN lens group GRN having a negative refractivepower, wherein upon zooming, a distance between the front lens group GFSand the M1 lens group GM1 changes, a distance between the M1 lens groupGM1 and the M2 lens group GM2 changes, and a distance between the M2lens group GM2 and the RN lens group GRN changes, upon focusing from aninfinite distant object to a short distant object, the RN lens group GRNmoves, and the M2 lens group GM2 comprises an A lens group thatsatisfies a following conditional expression (1),

1.10<fvr/fTM2<2.00   (1)

where

fvr: a focal length of the A lens group, and

fTM2: a focal length of the M2 lens group GM2 in a telephoto end state.

The zoom optical system ZL according to this embodiment may be a zoomoptical system ZL(2) shown in FIG. 6 , a zoom optical system ZL(3) shownin FIG. 11 , a zoom optical system ZL(4) shown in FIG. 16 , or a zoomoptical system ZL(5) shown in FIG. 21 .

The zoom optical system of this embodiment includes at least four lensgroups, and changes the distances between lens groups upon zooming fromthe wide-angle end state to the telephoto end state, thereby allowingfavorable aberration correction upon zooming to be facilitated. Focusingwith the RN lens group GRN can reduce the size and weight of the RN lensgroup GRN, that is, the focusing lens group.

The conditional expression (1) defines the ratio of the focal length ofthe A lens group to the focal length of the M2 lens group GM2 in thetelephoto end state. By satisfying the conditional expression (1),variation in various aberrations including the spherical aberration uponzooming from the wide-angle end to the telephoto end can be suppressed,and occurrence of various aberrations including the decentering comaaberration upon blur correction can be suppressed.

If the corresponding value of the conditional expression (1) of the zoomoptical system of this embodiment exceeds the upper limit value, therefractive power of the M2 lens group GM2 in the telephoto end statebecomes strong, and it is difficult to suppress variation in variousaberrations including the spherical aberration upon zooming from thewide-angle end to the telephoto end. Note that setting of the upperlimit value of the conditional expression (1) to 1.95 can more securelyachieve the advantageous effects of this embodiment. To further securethe advantageous effects of this embodiment, it is preferable that theupper limit value of the conditional expression (1) be 1.90.

If the corresponding value of the conditional expression (1) of the zoomoptical system of this embodiment falls below the lower limit value, therefractive power of the A lens group becomes strong, and it becomesdifficult to suppress occurrence of various aberrations including thedecentering coma aberration upon blur correction. Note that setting ofthe lower limit value of the conditional expression (1) to 1.15 can moresecurely achieve the advantageous effects of this embodiment. To furthersecure the advantageous effects of this embodiment, it is preferablethat the lower limit value of the conditional expression (1) be 1.20.

According to the zoom optical system of this embodiment, reduction insize and weight of the focusing lens group can achieve high-speed AF andsilence during AF without increasing the size of the lens barrel.Furthermore, variation of aberrations upon zooming from the wide-angleend state to the telephoto end state, and variation of aberrations uponfocusing from an infinite distant object to a short distant object canbe favorably suppressed. The optical apparatus, the imaging apparatus,and the method for manufacturing the zoom optical system according tothis embodiment can also achieve analogous advantageous effects.

In the zoom optical system according to this embodiment, preferably,upon zooming from a wide-angle end state to a telephoto end state, thefront lens group GFS moves toward the object. Accordingly, the entirelength of the lens at the wide-angle end state can be reduced, which canfacilitate reduction in the size of the zoom optical system.

In the zoom optical system according to this embodiment, preferably,upon zooming from a wide-angle end state to a telephoto end state, alens group nearest to the object in the M1 lens group GM1 is fixed withrespect to an image surface. Accordingly, degradation in performance dueto manufacturing errors is suppressed, which can securemass-productivity.

In the zoom optical system according to this embodiment, preferably, theA lens group consists of, in order from the object: a lens having anegative refractive power; and a lens having a positive refractivepower.

It is desirable that the zoom optical system of this embodimentcomprising the A lens group satisfy a following conditional expression(2),

1.00<nvrN/nvrP<1.25   (2)

where

nvrN: a refractive index of the lens having the negative refractivepower in the A lens group, and

nvrP: a refractive index of the lens having the positive refractivepower in the A lens group.

The conditional expression (2) defines the ratio of the refractive indexof the lens that is in the A lens group and has the negative refractivepower to the refractive index of the lens that is in the A lens groupand has the positive refractive power. By satisfying the conditionalexpression (2), degradation in performance upon blur correction by the Alens group can be effectively suppressed.

If the corresponding value of the conditional expression (2) exceeds theupper limit value, the refractive index of the lens that is in the Alens group and has a positive refractive power decreases, thedecentering coma aberration caused upon blur correction excessivelyoccurs, and it becomes difficult to correct the aberration. Setting ofthe upper limit value of the conditional expression (2) to 1.22 can moresecurely achieve the advantageous effects of this embodiment. To furthersecure the advantageous effects of this embodiment, it is preferablethat the upper limit value of the conditional expression (2) be 1.20.

If the corresponding value of the conditional expression (2) falls belowthe lower limit value, the refractive index of the lens that is in the Alens group and has the negative refractive power becomes low, and itbecomes difficult to correct the decentering coma aberration upon blurcorrection. Setting of the lower limit value of the conditionalexpression (2) to 1.03 can more securely achieve the advantageouseffects of this embodiment. To further secure the advantageous effectsof this embodiment, it is preferable that the lower limit value of theconditional expression (2) be 1.05.

It is also desirable that the zoom optical system comprising the A lensgroup satisfy a following conditional expression (3),

0.30<vvrN/vvrP<0.90   (3)

where

vvrN: an Abbe number of the lens having the negative refractive power inthe A lens group, and

vvrP: an Abbe number of the lens having the positive refractive power inthe A lens group.

The conditional expression (3) defines the ratio of the Abbe number ofthe lens that is in the A lens group and has a negative refractive powerto the Abbe number of the lens that is in the A lens group and has apositive refractive power. By satisfying the conditional expression (3),degradation in performance upon blur correction can be effectivelysuppressed.

If the corresponding value of the conditional expression (3) exceeds theupper limit value, the Abbe number of the lens that is in the A lensgroup and has the positive refractive power decreases, and it becomesdifficult to correct the chromatic aberration caused upon blurcorrection. Setting of the upper limit value of the conditionalexpression (3) to 0.85 can more securely achieve the advantageouseffects of this embodiment. To further secure the advantageous effectsof this embodiment, it is preferable that the upper limit value of theconditional expression (3) be 0.80.

If the corresponding value of the conditional expression (3) falls belowthe lower limit value, the Abbe number of the lens that is in the A lensgroup and has a negative refractive power decreases, and it becomesdifficult to correct the chromatic aberration caused upon blurcorrection. Setting of the lower limit value of the conditionalexpression (3) to 0.35 can more securely achieve the advantageouseffects of this embodiment. To further secure the advantageous effectsof this embodiment, it is preferable that the lower limit value of theconditional expression (3) be 0.40.

It is desirable that the zoom optical system according to thisembodiment satisfy a following conditional expression (4),

0.15<(−ftM1)/f1<0.35   (4)

where

fTM1: a focal length of the M1 lens group GM1 in a telephoto end state,and

f1: a focal length of the front lens group GFS.

The conditional expression (4) defines the ratio of the focal length ofthe M1 lens group GM1 to the focal length of the front lens group GFS inthe telephoto end state. By satisfying the conditional expression (4),various aberrations including the spherical aberration upon zooming fromthe wide-angle end to the telephoto end can be suppressed.

If the corresponding value of the conditional expression (4) exceeds theupper limit value, the refractive power of the front lens group GFSbecomes strong, and it is difficult to correct various aberrationsincluding the spherical aberration upon zooming from the wide-angle endto the telephoto end. Setting of the upper limit value of theconditional expression (4) to 0.33 can more securely achieve theadvantageous effects of this embodiment. To further secure theadvantageous effects of this embodiment, it is preferable that the upperlimit value of the conditional expression (4) be 0.31.

If the corresponding value of the conditional expression (4) falls belowthe lower limit value, the refractive power of the M1 lens group GM1becomes strong, and it is difficult to suppress variation in variousaberrations including the spherical aberration upon zooming from thewide-angle end to the telephoto end. Setting of the lower limit value ofthe conditional expression (4) to 0.16 can more securely achieve theadvantageous effects of this embodiment. To further secure theadvantageous effects of this embodiment, it is preferable that the lowerlimit value of the conditional expression (4) be 0.17.

It is desirable that the zoom optical system according to thisembodiment satisfy a following conditional expression (5),

0.20<fTM2/f1<0.40   (5)

where

f1: a focal length of the front lens group GFS.

The conditional expression (5) defines the ratio of the focal length ofthe M2 lens group GM2 to the focal length of the front lens group GFS inthe telephoto end state. By satisfying the conditional expression (5),various aberrations including the spherical aberration upon zooming fromthe wide-angle end to the telephoto end can be suppressed.

If the corresponding value of the conditional expression (5) exceeds theupper limit value, the refractive power of the front lens group GFSbecomes strong, and it is difficult to correct various aberrationsincluding the spherical aberration upon zooming from the wide-angle endto the telephoto end. Setting of the upper limit value of theconditional expression (5) to 0.37 can more securely achieve theadvantageous effects of this embodiment. To further secure theadvantageous effects of this embodiment, it is preferable that the upperlimit value of the conditional expression (5) be 0.34.

If the corresponding value of the conditional expression (5) falls belowthe lower limit value, the refractive power of the M2 lens group GM2becomes strong, and it is difficult to suppress variation in variousaberrations including the spherical aberration upon zooming from thewide-angle end to the telephoto end. Setting of the lower limit value ofthe conditional expression (5) to 0.22 can more securely achieve theadvantageous effects of this embodiment. To further secure theadvantageous effects of this embodiment, it is preferable that the lowerlimit value of the conditional expression (5) be 0.24.

In the zoom optical system according to this embodiment, preferably, theA lens group is a vibration-proof lens group movable in a directionorthogonal to an optical axis to correct an imaging positiondisplacement due to a camera shake or the like. Accordingly, degradationin performance upon blur correction can be effectively suppressed.

Preferably, the zoom optical system according to this embodiment furthercomprises a negative meniscus lens that has a concave surface facing theobject, which is provided contiguous to the RN lens group on an imageside. The configuration may further comprise, in order from the object:a lens having a negative refractive power; and a lens having a positiverefractive power, which are provided contiguous to the RN lens group onan image side. Accordingly, various aberrations including the comaaberration can be effectively corrected.

It is preferable that the zoom optical system according to thisembodiment satisfy a following conditional expression (6),

0.70<(−fN)/fP<2.00   (6)

where

fN: a focal length of a lens having a strongest negative refractivepower among lenses adjacent to the image side of the RN lens group GRN,and

fP: a focal length of a lens having a strongest positive refractivepower among lenses adjacent to the image side of the RN lens group GRN.

The conditional expression (6) described above defines the ratio of thefocal length of the lens that has the strongest negative refractivepower among the lenses adjacent to the image side of the RN lens groupGRN to the focal length of the lens that has the strongest positiverefractive power among the lenses adjacent to the image side of the RNlens group GRN. By satisfying the conditional expression (6), variousaberrations including the coma aberration can be effectively corrected.

If the corresponding value of the conditional expression (6) exceeds theupper limit value, the refractive power of the lens that is disposed tothe image side of the focusing lens group and has a positive refractivepower becomes strong, and the coma aberration occurs excessively.Setting of the upper limit value of the conditional expression (6) to1.90 can more securely achieve the advantageous effects of thisembodiment. To further secure the advantageous effects of thisembodiment, it is preferable that the upper limit value of theconditional expression (6) be 1.80.

If the corresponding value of the conditional expression (6) falls belowthe lower limit value, the refractive power of the lens that is disposedto the image side of the focusing lens group and has a negativerefractive power becomes strong, and the coma aberration is excessivelycorrected. Setting of the lower limit value of the conditionalexpression (6) to 0.80 can more securely achieve the advantageouseffects of this embodiment. To further secure the advantageous effectsof this embodiment, it is preferable that the lower limit value of theconditional expression (6) be 0.90.

It is preferable that the zoom optical system according to thisembodiment satisfy a following conditional expression (7),

1.80<f1/fw<3.50   (7)

where

fw: a focal length of the zoom optical system in a wide-angle end state,and

f1: a focal length of the front lens group GFS.

The conditional expression (7) defines the ratio of the focal length ofthe front lens group GFS to the focal length of the zoom optical systemin the wide-angle end state. By satisfying the conditional expression(7), the size of the lens barrel can be prevented from increasing, andvarious aberrations including the spherical aberration upon zooming fromthe wide-angle end to the telephoto end can be suppressed.

If the corresponding value of the conditional expression (7) exceeds theupper limit value, the refractive power of the front lens group GFSbecomes weak, and the size of lens barrel increases. Setting of theupper limit value of the conditional expression (7) to 3.30 can moresecurely achieve the advantageous effects of this embodiment. To furthersecure the advantageous effects of this embodiment, it is preferable toset the upper limit value of the conditional expression (7) to 3.10.

If the corresponding value of the conditional expression (7) falls belowthe lower limit value, the refractive power of the front lens group GFSbecomes strong, and it is difficult to correct various aberrationsincluding the spherical aberration upon zooming from the wide-angle endto the telephoto end. Setting of the lower limit value of theconditional expression (7) to 1.90 can more securely achieve theadvantageous effects of this embodiment. To further secure theadvantageous effects of this embodiment, it is preferable to set thelower limit value of the conditional expression (7) to 2.00, and it ismore preferable to set the lower limit value of the conditionalexpression (7) to 2.10.

It is preferable that the zoom optical system according to thisembodiment satisfy a following conditional expression (8),

3.70<f1/(−fTM1)<5.00   (8)

where

fTM1: a focal length of the M1 lens group GM1 in a telephoto end state,and

f1: a focal length of the front lens group GFS.

The conditional expression (8) defines the ratio of the focal length ofthe front lens group GFS to the focal length of the M1 lens group GM1.By satisfying the conditional expression (8), various aberrationsincluding the spherical aberration upon zooming from the wide-angle endto the telephoto end can be suppressed.

If the corresponding value of the conditional expression (8) exceeds theupper limit value, the refractive power of the M1 lens group GM1 becomesstrong, and it is difficult to suppress variation in various aberrationsincluding the spherical aberration upon zooming from the wide-angle endto the telephoto end. Setting of the upper limit value of theconditional expression (8) to 4.90 can more securely achieve theadvantageous effects of this embodiment. To further secure theadvantageous effects of this embodiment, it is preferable to set theupper limit value of the conditional expression (8) to 4.80.

If the corresponding value of the conditional expression (8) falls belowthe lower limit value, the refractive power of the front lens group GFSbecomes strong, and it is difficult to correct various aberrationsincluding the spherical aberration upon zooming from the wide-angle endto the telephoto end. Setting of the lower limit value of theconditional expression (8) to 3.90 can more securely achieve theadvantageous effects of this embodiment. To further secure theadvantageous effects of this embodiment, it is preferable to set thelower limit value of the conditional expression (8) to 3.95.

It is preferable that the zoom optical system according to thisembodiment satisfy a following conditional expression (9)

3.20<f1/fTM2<5.00   (9)

where

f1: a focal length of the front lens group GFS.

The conditional expression (9) defines the ratio of the focal length ofthe front lens group GFS to the focal length of the M2 lens group GM2.By satisfying the conditional expression (9), various aberrationsincluding the spherical aberration upon zooming from the wide-angle endto the telephoto end can be suppressed.

If the corresponding value of the conditional expression (9) exceeds theupper limit value, the refractive power of the M2 lens group GM2 becomesstrong, and it is difficult to suppress variation in various aberrationsincluding the spherical aberration upon zooming from the wide-angle endto the telephoto end. Setting of the upper limit value of theconditional expression (9) to 4.80 can more securely achieve theadvantageous effects of this embodiment. To further secure theadvantageous effects of this embodiment, it is preferable to set theupper limit value of the conditional expression (9) to 4.60.

If the corresponding value of the conditional expression (9) falls belowthe lower limit value, the refractive power of the front lens group GFSbecomes strong, and it is difficult to correct various aberrationsincluding the spherical aberration upon zooming from the wide-angle endto the telephoto end. Setting of the lower limit value of theconditional expression (9) to 3.40 can more securely achieve theadvantageous effects of this embodiment. To further secure theadvantageous effects of this embodiment, it is preferable to set thelower limit value of the conditional expression (9) to 3.60.

An optical apparatus and an imaging apparatus according to thisembodiment comprise the zoom optical system having the configurationdescribed above. As a specific example, a camera (corresponding to theimaging apparatus of the invention of the present application) includingthe aforementioned zoom optical system ZL is described with reference toFIG. 26 . As shown in FIG. 26 , this camera 1 has a lens assemblyconfiguration including a replaceable imaging lens 2. The zoom opticalsystem having the configuration described above is provided in theimaging lens 2. That is, the imaging lens 2 corresponds to the opticalapparatus of the invention of the present application. The camera 1 is adigital camera. Light from an object (subject), not shown, is collectedby the imaging lens 2, and reaches an imaging element 3. Accordingly,the light from the subject is imaged by the imaging element 3, andrecorded as a subject image in a memory, not shown. As described above,a photographer can take an image of the subject through the camera 1.Note that this camera may be a mirrorless camera, or a single-lensreflex type camera including a quick return mirror.

According to the configuration described above, the camera 1 mountedwith the zoom optical system ZL described above in the imaging lens 2can achieve high-speed AF and silence during AF without increasing thesize of the lens barrel by reducing the size and weight of the focusinglens group. Furthermore, variation of aberrations upon zooming from thewide-angle end state to the telephoto end state, and variation ofaberrations upon focusing from an infinite distant object to a shortdistant object can be favorably suppressed, and a favorable opticalperformance can be achieved.

Subsequently, referring to FIG. 27 , an overview of a method formanufacturing the aforementioned zoom optical system ZL is described.First, arrange, in order from an object, a front lens group GFS having apositive refractive power, an M1 lens group GM1 having a negativerefractive power, an M2 lens group GM2 having a positive refractivepower, and an RN lens group GRN having a negative refractive power (stepST1). Then, achieve a configuration such that upon zooming, a distancebetween the front lens group GFS and the M1 lens group GM1 changes, adistance between the M1 lens group GM1 and the M2 lens group GM2changes, and a distance between the M2 lens group GM2 and the RN lensgroup GRN changes (step ST2). In this case, the RN lens group GRN isconfigured to move upon focusing from an infinite distant object to ashort distant object (step ST3), and lenses are arranged such that theM2 lens group GM2 comprises the A lens group satisfying a predeterminedconditional expression (step ST4).

EXAMPLES

Hereinafter, zoom optical systems (zoom lens) ZL according to theexamples of this embodiment are described with reference to thedrawings. FIGS. 1, 6, 11, 16 and 21 are sectional views showing theconfigurations and refractive power distributions of the zoom opticalsystems ZL {ZL (1) to ZL(5)} according to first to fifth examples. Atlower parts of the sectional views of the zoom optical systems ZL(1) toZL(5), the movement direction of each lens group along the optical axisduring zooming from the wide-angle end state (W) to the telephoto endstate (T) is indicated by a corresponding arrow. Furthermore, themovement direction during focusing the focusing group GRN from infinityto a short distant object is indicated by an arrow accompanied bycharacters “FOCUSING.”

FIGS. 1, 6, 11, 16 and 21 show each lens group by a combination of asymbol G and a numeral or alphabet (s), and show each lens by acombination of a symbol L and a numeral. In this case, to prevent thetypes and numbers of symbols and numerals from increasing and beingcomplicated, the lens groups and the like are indicated using thecombinations of symbols and numerals independently on anexample-by-example basis. Accordingly, even though the same combinationsof symbols and numerals are used among the examples, the combinations donot mean the same configurations.

Tables 1 to 5 are hereinafter shown below. Tables 1 to 5 are tablesrepresenting various data in the first to fifth examples. In eachexample, d-line (wavelength 587.562 nm) and g-line (wavelength 435.835nm) are selected as calculation targets of aberration characteristics.

In [Lens data] tables, the surface number denotes the order of opticalsurfaces from the object along a light beam traveling direction, Rdenotes the radius of curvature (a surface whose center of curvature isnearer to the image is assumed to have a positive value) of each opticalsurface, D denotes the surface distance, which is the distance on theoptical axis from each optical surface to the next optical surface (orthe image surface), nd denotes the refractive index of the material ofan optical element for the d-line, and vd denotes the Abbe number of thematerial of an optical element with reference to the d-line. The objectsurface denotes the surface of an object. “∞” of the radius of curvatureindicates a flat surface or an aperture. (Stop S) indicates an aperturestop S. The image surface indicates an image surface I. The descriptionof the air refractive index nd=1.00000 is omitted.

In [Various data] tables, f denotes the focal length of the entire zoomlens, FNO denotes the f-number, 2ω denotes the angle of view(represented in units of ° (degree); ω denotes the half angle of view),and Ymax denotes the maximum image height. TL denotes the distanceobtained by adding BF to the distance on the optical axis from the lensforefront surface to the lens last surface upon focusing on infinity. BFdenotes the distance (back focus) on the optical axis from the lens lastsurface to the image surface I upon focusing on infinity. Note thatthese values are represented for zooming states of the wide-angle end(W), the intermediate focal length (M), and the telephoto end (T).

[Variable distance data] tables show the surface distances at surfacenumbers (e.g., surface numbers 5, 13, 25 and 29 in First Example) towhich the surface distance of “Variable” in the table representing [Lensdata] correspond. This shows the surface distances in the zooming statesof the wide-angle end (W), the intermediate focal length (M) and thetelephoto end (T) upon focusing on infinity and a short distant object.

[Lens group data] tables show the starting surfaces (the surfacesnearest to the object) and the focal lengths of the first to fifth lensgroups (or the first to fourth lens groups or the first to sixth lensgroups).

[Conditional expression corresponding value] tables show valuescorresponding to the conditional expressions (1) to (9) described above.

Hereinafter, for all the data values, the listed focal length f, radiusof curvature R, surface distance D, other lengths and the like aretypically represented in “mm” if not otherwise specified. However, theoptical system can exert equivalent optical performances even if beingproportionally magnified or proportionally reduced. Consequently, therepresentation is not limited thereto.

The above descriptions of the tables are common to all the examples.Hereinafter, redundant description is omitted.

First Example

The first example is described with reference to FIG. 1 and Table 1.FIG. 1 shows a lens configuration of a zoom optical system according tothe first example of this embodiment. The zoom optical system ZL(1)according to this example consists of, in order from the object: a firstlens group G1 having a positive refractive power; a second lens group G2having a negative refractive power; a third lens group G3 having apositive refractive power; a fourth lens group G4 having a negativerefractive power; and a fifth lens group G5 having a positive refractivepower. The sign (+) or (−) assigned to each lens group symbol indicatesthe refractive power of the corresponding lens group. This similarlyapplies to all the following examples.

In relation to the embodiment described above, in this configuration,the first lens group G1 corresponds to the front lens group GFS, thesecond lens group G2 corresponds to the M1 lens group GM1, the thirdlens group G3 corresponds to the M2 lens group GM2, and the fourth lensgroup G4 corresponds to the RN lens group GRN.

The first lens group G1 consists of, in order from the object: apositive convexo-planar lens L11 having a convex surface facing theobject; and a positive cemented lens consisting of a negative meniscuslens L12 having a convex surface facing the object, and a positivemeniscus lens L13 having a convex surface facing the object.

The second lens group G2 consists of, in order from the object: anegative meniscus lens L21 having a convex surface facing the object; apositive biconvex lens L22; a negative biconcave lens L23; and anegative meniscus lens L24 having a concave surface facing the object.

The third lens group G3 consists of, in order from the object: apositive cemented lens consisting of a negative meniscus lens L31 havinga convex surface facing the object, and a positive biconvex lens L32; apositive cemented lens consisting of a positive biconvex lens L33, and anegative biconcave lens L34; an aperture stop S; a negative cementedlens consisting of a negative meniscus lens L35 having a convex surfacefacing the object, and a positive biconvex lens L36; and a positivebiconvex lens L37.

The fourth lens group G4 consists of, in order from the object: apositive meniscus lens L41 having a concave surface facing the object;and a negative biconcave lens L42.

The fifth lens group G5 consists of, in order from the object: anegative meniscus lens L51 having a concave surface facing the object;and a positive biconvex lens L52.

In the optical system according to this example, focusing from a longdistant object to a short distant object is performed by moving thefourth lens group G4 in the image surface direction.

The zoom optical system according to this example corrects the imagingposition displacement due to a camera shake or the like by moving thepositive cemented lens that consists of the negative meniscus lens L31having the convex surface facing the object and the positive biconvexlens L32, in a direction orthogonal to the optical axis. That is, thelenses L31 and L32 constitute the vibration-proof lens group, andcorrespond to the A lens group of the present invention and thisembodiment.

To correct a rotational blur with an angle θ at a lens having the focallength f of the entire system and a vibration proof coefficient K (theratio of the amount of image movement on the image forming surface tothe amount of movement of the movable lens group upon blur correction),the movable lens group for blur correction may be moved in a directionorthogonal to the optical axis by (f·tan θ)/K. At the wide-angle end inthe first example, the vibration proof coefficient is 1.65, and thefocal length is 72.1 mm. Accordingly, the amount of movement of thevibration-proof lens group to correct a rotational blur by 0.30° is 0.23mm. In the telephoto end state in the first example, the vibration proofcoefficient is 2.10, and the focal length is 292.0 mm. Accordingly, theamount of movement of the vibration-proof lens group to correct arotational blur by 0.20° is 0.49 mm.

The following Table 1 lists the values of data on the optical systemaccording to this example. In Table 1, f denotes the focal length, andBF denotes the back focus.

TABLE 1 First Example [Lens data] Surface No. R D nd νd Object surface ∞1 109.4870 4.600 1.48749 70.31 2 ∞ 0.200 3 101.1800 1.800 1.62004 36.404 49.8109 7.200 1.49700 81.61 5 385.8166 Variable 6 176.0187 1.7001.69680 55.52 7 31.3680 5.150 8 32.6087 5.500 1.78472 25.64 9 −129.76341.447 10 −415.4105 1.300 1.77250 49.62 11 34.3083 4.300 12 −33.15021.200 1.85026 32.35 13 −203.5644 Variable 14 70.9040 1.200 1.80100 34.9215 30.2785 5.900 1.64000 60.20 16 −70.1396 1.500 17 34.0885 6.0001.48749 70.31 18 −42.6106 1.300 1.80610 40.97 19 401.2557 2.700 20 ∞14.110  (Stop S) 21 350.0000 1.200 1.83400 37.18 22 30.1592 4.8001.51680 63.88 23 −94.9908 0.200 24 66.3243 2.800 1.80100 34.92 25−132.5118 Variable 26 −92.0997 2.200 1.80518 25.45 27 −44.0090 6.500 28−36.9702 1.000 1.77250 49.62 29 68.3346 Variable 30 −24.5000 1.4001.62004 36.40 31 −41.1519 0.200 32 106.0000 3.800 1.67003 47.14 33−106.0000 BF Image surface ∞ [Various data] Zooming ratio 4.05 W M T f72.1 100.0 292.0 FNO 4.49 4.86 5.88 2ω 33.96 24.48 8.44 Ymax 21.60 21.6021.60 TL 190.13 205.07 245.82 BF 39.12 46.45 67.12 [Variable distancedata] W M T W M T Short Short Short Infinity Infinity Infinity distancedistance distance d5 6.204 21.150 61.895 6.204 21.150 61.895 d13 30.00022.666 2.000 30.000 22.666 2.000 d25 2.180 3.742 3.895 2.837 4.562 5.614d29 21.418 19.856 19.703 20.761 19.036 17.984 [Lens group data] GroupStarting surface f G1 1 145.319 G2 6 −29.546 G3 14 38.298 G4 26 −48.034G5 30 324.470 [Conditional expression corresponding value] (1) fvr/fTM2= 1.755 (2) nvrN/nvrP = 1.098 (3) νvrN/νvrP = 0.580 (4) (−fTM1)/f1 =0.203 (5) fTM2/f1 = 0.264 (6) (−fN)/fP = 1.266 (7) f1/fw = 2.016 (8)f1/(−fTM1) = 4.918 (9) f1/fTM2 = 3.794

FIGS. 2A and 2B are graphs showing various aberrations of the zoomoptical system having the vibration-proof function according to thefirst example upon focusing on infinity in the wide-angle end state, andgraphs showing meridional lateral aberrations when blur correction isapplied to a rotational blur by 0.30°, respectively. FIG. 3 is graphsshowing various aberrations of the zoom optical system having thevibration-proof function according to the first example upon focusing oninfinity in the intermediate focal length state. FIGS. 4A and 4B aregraphs showing various aberrations of the zoom optical system having thevibration-proof function according to the first example upon focusing oninfinity in the telephoto end state, and graphs showing meridionallateral aberrations when blur correction is applied to a rotational blurby 0.20°, respectively. FIGS. 5A, 5B and 5C are graphs showing variousaberrations of the zoom optical system according to the first exampleupon focusing on a short distant object in the wide-angle end state, theintermediate focal length state, and the telephoto end state,respectively.

In the aberration graphs of FIGS. 2 to 5 , FNO denotes the f-number, NAdenotes the numerical aperture, and Y denotes the image height. Notethat the spherical aberration graph shows the value of the f-number orthe numerical aperture corresponding to the maximum aperture. Theastigmatism graph and the distortion graph show the maximum value of theimage height. The coma aberration graph shows the value of each imageheight. d denotes the d-line (λ=587.6 nm), and g denotes the g-line(λ=435.8 nm). In the astigmatism graph, solid lines indicate sagittalimage surfaces, and broken lines indicate meridional image surfaces.Note that symbols analogous to those in this example are used also inthe aberration graphs in the following examples.

The graphs showing various aberrations show that the zoom optical systemaccording to this example favorably corrects the various aberrations andhas excellent image forming performances from the wide-angle end stateto the telephoto end state, and further has excellent image formingperformances also upon focusing on a short distant object.

Second Example

FIG. 6 shows a lens configuration of a zoom optical system according tothe second example of this embodiment. The zoom optical system accordingto this example consists of, in order from the object: a first lensgroup G1 having a positive refractive power; a second lens group G2having a negative refractive power; a third lens group G3 having anegative refractive power; a fourth lens group G4 having a positiverefractive power; a fifth lens group G5 having a negative refractivepower; and a sixth lens group G6 having a positive refractive power.

In relation to the embodiment described above, in this configuration,the first lens group G1 corresponds to the front lens group GFS, thesecond lens group G2 and the third lens group G3 correspond to the M1lens group GM1, the fourth lens group G4 corresponds to the M2 lensgroup GM2, and the fifth lens group G5 corresponds to the RN lens groupGRN.

The first lens group G1 consists of, in order from the object: apositive convexo-planar lens L11 having a convex surface facing theobject; and a positive cemented lens consisting of a negative meniscuslens L12 having a convex surface facing the object, and a positivemeniscus lens L13 having a convex surface facing the object.

The second lens group G2 consists of, in order from the object: anegative meniscus lens L21 having a convex surface facing the object; apositive biconvex lens L22; and a negative biconcave lens L23.

The third lens group G3 consists of a negative meniscus lens L31 havinga concave surface facing the object.

The fourth lens group G4 consists of, in order from the object: apositive cemented lens consisting of a negative meniscus lens L41 havinga convex surface facing the object, and a positive biconvex lens L42; apositive cemented lens consisting of a positive biconvex lens L43, and anegative biconcave lens L44; an aperture stop S; a negative cementedlens consisting of a negative meniscus lens L45 having a convex surfacefacing the object, and a positive biconvex lens L46; and a positivebiconvex lens L47.

The fifth lens group G5 consists of, in order from the object: apositive meniscus lens L51 having a concave surface facing the object;and a negative biconcave lens L52.

The sixth lens group G6 consists of, in order from the object: anegative meniscus lens L61 having a concave surface facing the object;and a positive biconvex lens L62.

In the optical system according to this example, focusing from a longdistant object to a short distant object is performed by moving thefifth lens group G5 in the image surface direction. The imaging positiondisplacement due to a camera shake or the like is corrected by movingthe positive cemented lens that consists of the negative meniscus lensL41 having the convex surface facing the object and the positivebiconvex lens L42, in a direction orthogonal to the optical axis. Thatis, the lenses L41 and L42 constitute the vibration-proof lens group,and correspond to the A lens group of the present invention and thisembodiment.

Note that to correct a rotational blur with an angle θ at a lens havingthe focal length f of the entire system and a vibration proofcoefficient K (the ratio of the amount of image movement on the imageforming surface to the amount of movement of the movable lens group uponblur correction), the movable lens group for blur correction is moved ina direction orthogonal to the optical axis by (f·tan θ)/K. At thewide-angle end in the second example, the vibration proof coefficient is1.66, and the focal length is 72.1 mm. Accordingly, the amount ofmovement of the vibration-proof lens group to correct a rotational blurby 0.30° is 0.23 mm. In the telephoto end state in the second example,the vibration proof coefficient is 2.10, and the focal length is 292.0mm. Accordingly, the amount of movement of the vibration-proof lensgroup to correct a rotational blur by 0.20° is 0.49 mm.

The following Table 2 lists the values of data on the optical systemaccording to this example.

TABLE 2 Second Example [Lens data] Surface No. R D nd νd Object surface∞ 1 107.5723 4.600 1.48749 70.32 2 ∞ 0.200 3 96.9007 1.800 1.62004 36.404 47.8324 7.200 1.49700 81.61 5 361.3792 Variable 6 139.8663 1.7001.69680 55.52 7 33.7621 6.806 8 33.5312 5.500 1.78472 25.64 9 −139.83480.637 10 −492.0620 1.300 1.80400 46.60 11 35.1115 Variable 12 −34.61631.200 1.83400 37.18 13 −377.1306 Variable 14 74.8969 1.200 1.80100 34.9215 31.6202 5.900 1.64000 60.19 16 −69.0444 1.500 17 34.2668 6.0001.48749 70.32 18 −42.8334 1.300 1.80610 40.97 19 434.9585 2.700 20 ∞14.312  (Stop S) 21 350.0000 1.200 1.83400 37.18 22 30.4007 4.8001.51680 63.88 23 −98.0361 0.200 24 68.9306 2.800 1.80100 34.92 25−129.3404 Variable 26 −90.5065 2.200 1.80518 25.45 27 −44.1796 6.500 28−37.6907 1.000 1.77250 49.62 29 68.3000 Variable 30 −24.5545 1.4001.62004 36.40 31 −41.7070 0.200 32 106.0000 3.800 1.67003 47.14 33−106.0000 BF Image surface ∞ [Various data] Zooming ratio 4.05 W M T f72.1 100.0 292.0 FNO 4.53 4.89 5.88 2ω 33.98 24.48 8.44 Ymax 21.60 21.6021.60 TL 190.82 206.02 245.82 BF 39.12 46.27 66.46 [Variable distancedata] W M T W M T Short Short Short Infinity Infinity Infinity distancedistance distance d5 2.861 18.057 57.861 2.861 18.057 57.861 d11 5.7275.812 6.883 5.727 5.812 6.883 d13 30.500 23.259 2.000 30.500 23.2592.000 d25 2.246 3.634 3.634 2.888 4.436 5.329 d29 22.411 21.023 21.02321.770 20.221 19.329 [Lens group data] Group Starting surface f G1 1141.867 G2 6 −104.910 G3 12 −45.774 G4 14 38.681 G5 26 −48.266 G6 30340.779 [Conditional expression corresponding value] (1) fvr/fTM2 =1.764 (2) nvrN/nvrP = 1.098 (3) νvrN/νvrP = 0.580 (4) (−fTM1)/f1 = 0.208(5) fTM2/f1 = 0.273 (6) (−fN)/fP = 1.248 (7) f1/fw = 1.968 (8)f1/(−fTM1) = 4.804 (9) f1/fTM2 = 3.668

FIGS. 7A and 7B are graphs showing various aberrations of the zoomoptical system having the vibration-proof function according to thesecond example upon focusing on infinity in the wide-angle end state,and graphs showing meridional lateral aberrations when blur correctionis applied to a rotational blur by 0.30°, respectively. FIG. 8 is graphsshowing various aberrations of the zoom optical system having thevibration-proof function according to the second example upon focusingon infinity in the intermediate focal length state. FIGS. 9A and 9B aregraphs showing various aberrations of the zoom optical system having thevibration-proof function according to the second example upon focusingon infinity in the telephoto end state, and graphs showing meridionallateral aberrations when blur correction is applied to a rotational blurby 0.20°, respectively. FIGS. 10A, 10B and 10C are graphs showingvarious aberrations of the zoom optical system according to the secondexample upon focusing on a short distant object in the wide-angle endstate, the intermediate focal length state, and the telephoto end state,respectively.

The graphs showing various aberrations show that the zoom optical systemaccording to this example favorably corrects the various aberrations andhas excellent image forming performances from the wide-angle end stateto the telephoto end state, and further has excellent image formingperformances also upon focusing on a short distant object.

Third Example

FIG. 11 shows a lens configuration of a zoom optical system according tothe third example of this embodiment. The zoom optical system accordingto this example consists of, in order from the object: a first lensgroup G1 having a positive refractive power; a second lens group G2having a negative refractive power; a third lens group G3 having apositive refractive power; a fourth lens group G4 having a positiverefractive power; a fifth lens group G5 having a negative refractivepower; and a sixth lens group having a positive refractive power.

In relation to the embodiment described above, in this configuration,the first lens group G1 corresponds to the front lens group GFS, thesecond lens group G2 corresponds to the M1 lens group GM1, the thirdlens group G3 and the fourth lens group G4 correspond to the M2 lensgroup GM2, and the fifth lens group G5 corresponds to the RN lens groupGRN.

The first lens group G1 consists of, in order from the object: apositive convexo-planar lens L11 having a convex surface facing theobject; and a positive cemented lens consisting of a negative meniscuslens L12 having a convex surface facing the object, and a positivemeniscus lens L13 having a convex surface facing the object.

The second lens group G2 consists of, in order from the object: anegative meniscus lens L21 having a convex surface facing the object; apositive biconvex lens L22; a negative biconcave lens L23; and anegative meniscus lens L24 having a concave surface facing the object.

The third lens group G3 consists of, in order from the object: apositive cemented lens consisting of a negative meniscus lens L31 havinga convex surface facing the object, and a positive biconvex lens L32; apositive cemented lens consisting of a positive biconvex lens L33, and anegative biconcave lens L34; and an aperture stop S.

The fourth lens group G4 consists of, in order from the object: anegative cemented lens consisting of a negative meniscus lens L41 havinga convex surface facing the object, and a positive biconvex lens L42;and a positive biconvex lens L43.

The fifth lens group G5 consists of, in order from the object: apositive meniscus lens L51 having a concave surface facing the object;and a negative biconcave lens L52.

The sixth lens group G6 consists of, in order from the object: anegative meniscus lens L61 having a concave surface facing the object;and a positive biconvex lens L62.

In the optical system according to this example, focusing from a longdistant object to a short distant object is performed by moving thefifth lens group G5 in the image surface direction. The imaging positiondisplacement due to a camera shake or the like is corrected by movingthe positive cemented lens that consists of the negative meniscus lensL31 having the convex surface facing the object and the positivebiconvex lens L32, in a direction orthogonal to the optical axis. Thatis, the lenses L31 and L32 constitute the vibration-proof lens group,and correspond to the A lens group of the present invention and thisembodiment.

Note that to correct a rotational blur with an angle θ at a lens havingthe focal length f of the entire system and a vibration proofcoefficient K (the ratio of the amount of image movement on the imageforming surface to the amount of movement of the movable lens group uponblur correction), the movable lens group for blur correction is moved ina direction orthogonal to the optical axis by (f·tan θ)/K. At thewide-angle end in the third example, the vibration proof coefficient is1.65, and the focal length is 72.1 mm. Accordingly, the amount ofmovement of the vibration-proof lens group to correct a rotational blurby 0.30° is 0.23 mm. In the telephoto end state in the third example,the vibration proof coefficient is 2.10, and the focal length is 292.0mm. Accordingly, the amount of movement of the vibration-proof lensgroup to correct a rotational blur by 0.20° is 0.49 mm.

The following Table 3 lists the values of data on the optical systemaccording to this example.

TABLE 3 Third Example [Lens data] Surface No. R D nd νd Object surface ∞1 106.7563 4.600 1.48749 70.32 2 ∞ 0.200 3 99.4635 1.800 1.62004 36.40 449.2336 7.200 1.49700 81.61 5 332.7367 Variable 6 152.3830 1.700 1.6968055.52 7 31.0229 5.695 8 32.0867 5.500 1.78472 25.64 9 −139.5695 1.399 10−403.4713 1.300 1.77250 49.62 11 33.8214 4.300 12 −34.0003 1.200 1.8502632.35 13 −235.0206 Variable 14 69.3622 1.200 1.80100 34.92 15 29.84205.900 1.64000 60.19 16 −71.2277 1.500 17 34.4997 6.000 1.48749 70.32 18−43.1246 1.300 1.80610 40.97 19 382.2412 2.700 20 ∞ Variable (Stop S) 21350.0000 1.200 1.83400 37.18 22 30.6178 4.800 1.51680 63.88 23 −88.25080.200 24 66.4312 2.800 1.80100 34.92 25 −142.7832 Variable 26 −93.62062.200 1.80518 25.45 27 −44.3477 6.500 28 −37.1859 1.000 1.77250 49.62 2968.3000 Variable 30 −24.9508 1.400 1.62004 36.40 31 −42.7086 0.200 32106.0000 3.800 1.67003 47.14 33 −106.0000 BF Image surface ∞ [Variousdata] Zooming ratio 4.05 W M T f 72.1 100.0 292.0 FNO 4.49 4.85 5.88 2ω33.98 24.48 8.44 Ymax 21.60 21.60 21.60 TL 190.26 205.79 245.82 BF 39.1246.10 67.12 [Variable distance data] W M T W M T Short Short ShortInfinity Infinity Infinity distance distance distance d5 5.981 21.51061.535 5.981 21.510 61.535 d13 30.000 23.014 2.000 30.000 23.014 2.000d20 14.365 14.107 14.196 14.365 14.107 14.196 d25 2.202 3.476 3.6762.867 4.301 5.396 d29 21.004 19.988 19.700 20.339 19.163 17.979 [Lensgroup data] Group Starting surface f G1 1 145.335 G2 6 −29.607 G3 1448.974 G4 21 62.364 G5 26 −48.296 G6 30 336.791 [Conditional expressioncorresponding value] (1) fvr/fTM2 = 1.747 (2) nvrN/nvrP = 1.098 (3)νvrN/νvrP = 0.580 (4) (−fTM1)/f1 = 0.204 (5) fTM2/f1 = 0.264 (6)(−fN)/fP = 1.253 (7) f1/fw = 2.016 (8) f1/(−fTM1) = 4.909 (9) f1/fTM2 =3.786

FIGS. 12A and 12B are graphs showing various aberrations of the zoomoptical system having a vibration-proof function according to the thirdexample upon focusing on infinity in the wide-angle end state, andgraphs showing meridional lateral aberrations when blur correction isapplied to a rotational blur by 0.30°, respectively. FIG. 13 is graphsshowing various aberrations of the zoom optical system having thevibration-proof function according to the third example upon focusing oninfinity in the intermediate focal length state. FIGS. 14A and 14B aregraphs showing various aberrations of the zoom optical system having avibration-proof function according to the third example upon focusing oninfinity in the telephoto end state, and graphs showing meridionallateral aberrations when blur correction is applied to a rotational blurby 0.20°, respectively. FIGS. 15A, 15B and 15C are graphs showingvarious aberrations of the zoom optical system according to the thirdexample upon focusing on a short distant object in the wide-angle endstate, the intermediate focal length state, and the telephoto end state,respectively.

The graphs showing various aberrations show that the zoom optical systemaccording to this example favorably corrects the various aberrations andhas excellent image forming performances from the wide-angle end stateto the telephoto end state, and further has excellent image formingperformances also upon focusing on a short distant object.

Fourth Example

FIG. 16 shows a lens configuration of a zoom optical system according tothe fourth example of this embodiment. The zoom optical system accordingto this example consists of, in order from the object: a first lensgroup G1 having a positive refractive power; a second lens group G2having a negative refractive power; a third lens group G3 having apositive refractive power; and a fourth lens group G4 having a negativerefractive power.

In relation to the embodiment described above, in this configuration,the first lens group G1 corresponds to the front lens group GFS, thesecond lens group G2 corresponds to the M1 lens group GM1, the thirdlens group G3 corresponds to the M2 lens group GM2, and the fourth lensgroup G4 corresponds to the RN lens group GRN.

The first lens group G1 consists of, in order from the object: apositive convexo-planar lens L11 having a convex surface facing theobject; and a positive cemented lens consisting of a negative meniscuslens L12 having a convex surface facing the object, and a positivebiconvex lens L13.

The second lens group G2 consists of, in order from the object: anegative meniscus lens L21 having a convex surface facing the object; apositive biconvex lens L22; a negative biconcave lens L23; and anegative meniscus lens L24 having a concave surface facing the object.

The third lens group G3 consists of, in order from the object: apositive cemented lens consisting of a negative meniscus lens L31 havinga convex surface facing the object, and a positive biconvex lens L32; apositive cemented lens consisting of a positive biconvex lens L33, and anegative meniscus lens L34 having a concave surface facing the object;an aperture stop S; a negative cemented lens consisting of a negativemeniscus lens L35 having a convex surface facing the object, and apositive biconvex lens L36; and a positive biconvex lens L37.

The fourth lens group G4 consists of, in order from the object: apositive meniscus lens L41 having a concave surface facing the object;and a negative biconcave lens L42.

In the optical system according to this example, focusing from a longdistant object to a short distant object is performed by moving thefourth lens group G4 in the image surface direction.

The zoom optical system according to this example corrects the imagingposition displacement due to a camera shake or the like by moving thepositive cemented lens consisting of the negative meniscus lens L31having the convex surface facing the object and the positive biconvexlens L32, in a direction orthogonal to the optical axis. That is, thelenses L31 and L32 constitute the vibration-proof lens group, andcorrespond to the A lens group of the present invention and thisembodiment.

Note that to correct a rotational blur with an angle θ at a lens havingthe focal length f of the entire system and a vibration proofcoefficient K (the ratio of the amount of image movement on the imageforming surface to the amount of movement of the movable lens group uponblur correction), the movable lens group for blur correction may bemoved in a direction orthogonal to the optical axis by (f·tan θ)/K. Atthe wide-angle end in the fourth example, the vibration proofcoefficient is 1.64, and the focal length is 72.1 mm. Accordingly, theamount of movement of the vibration-proof lens group to correct arotational blur by 0.30° is 0.23 mm. In the telephoto end state in thefourth example, the vibration proof coefficient is 2.10, and the focallength is 292.0 mm. Accordingly, the amount of movement of thevibration-proof lens group to correct a rotational blur by 0.20° is 0.48mm.

The following Table 4 lists the values of data on the optical systemaccording to this example.

TABLE 4 Fourth Example [Lens data] Surface No. R D nd νd Object surface∞ 1 124.8083 4.600 1.48749 70.32 2 ∞ 0.200 3 111.5077 1.800 1.6200436.40 4 51.2894 7.200 1.49700 81.61 5 −4057.4569 Variable 6 1232.87161.700 1.69680 55.52 7 32.6209 3.624 8 33.1180 5.224 1.78472 25.64 9−126.9611 1.768 10 −243.6400 1.300 1.77250 49.62 11 37.7537 4.300 12−33.1285 1.200 1.85026 32.35 13 −124.4232 Variable 14 80.2408 1.2001.80100 34.92 15 32.8582 5.862 1.64000 60.19 16 −70.9140 1.500 1740.5722 6.000 1.48749 70.32 18 −43.0594 1.300 1.80610 40.97 19−2388.6437 2.700 20 ∞ 18.922  (Stop S) 21 812.4602 1.200 1.83400 37.1822 34.5376 5.275 1.51680 63.88 23 −59.1982 0.200 24 75.5608 3.2091.80100 34.92 25 −197.1038 Variable 26 −76.9453 2.263 1.80518 25.45 27−41.7537 6.500 28 −33.9973 1.000 1.77250 49.62 29 132.3165 BF Imagesurface ∞ [Various data] Zooming ratio 4.05 W M T f 72.1 100.0 292.0 FNO4.68 4.90 6.19 2ω 33.78 23.92 8.22 Ymax 21.60 21.60 21.60 TL 189.82210.78 245.82 BF 64.99 69.56 89.99 [Variable distance data] W M T W M TShort Short Short Infinity Infinity Infinity distance distance distanced5 2.000 22.956 58.000 2.000 22.956 58.000 d13 30.000 25.721 2.00030.000 25.721 2.000 d25 2.777 2.495 5.785 3.449 3.343 7.497 [Lens groupdata] Group Starting surface f G1 1 139.523 G2 6 −29.733 G3 14 41.597 G426 −54.885 [Conditional expression corresponding value] (1) fvr/fTM2 =1.728 (2) nvrN/nvrP = 1.098 (3) νvrN/νvrP = 0.580 (4) (−fTM1)/f1 = 0.213(5) fTM2/f1 = 0.298 (7) f1/fw = 1.935 (8) f1/(−fTM1) = 4.693 (9) f1/fTM2= 3.354

FIGS. 17A and 17B are graphs showing various aberrations of the zoomoptical system having the vibration-proof function according to thefourth example upon focusing on infinity in the wide-angle end state,and graphs showing meridional lateral aberrations when blur correctionis applied to a rotational blur by 0.30°, respectively. FIG. 18 isgraphs showing various aberrations of the zoom optical system having thevibration-proof function according to the fourth example upon focusingon infinity in the intermediate focal length state. FIGS. 19A and 19Bare graphs showing various aberrations of the zoom optical system havingthe vibration-proof function according to the fourth example uponfocusing on infinity in the telephoto end state, and graphs showingmeridional lateral aberrations when blur correction is applied to arotational blur by 0.20°, respectively. FIGS. 20A, 20B and 20C aregraphs showing various aberrations of the zoom optical system accordingto the fourth example upon focusing on a short distant object in thewide-angle end state, the intermediate focal length state, and thetelephoto end state, respectively.

The graphs showing various aberrations show that the zoom optical systemaccording to this example favorably corrects the various aberrations andhas excellent image forming performances from the wide-angle end stateto the telephoto end state, and further has excellent image formingperformances also upon focusing on a short distant object.

Fifth Example

FIG. 21 shows a lens configuration of a zoom optical system according tothe fifth example of this embodiment. The zoom optical system accordingto this example consists of, in order from the object: a first lensgroup G1 having a positive refractive power; a second lens group G2having a negative refractive power; a third lens group G3 having apositive refractive power; a fourth lens group G4 having a negativerefractive power; and a fifth lens group G5 having a positive refractivepower.

In relation to the embodiment described above, in this configuration,the first lens group G1 corresponds to the front lens group GFS, thesecond lens group G2 corresponds to the M1 lens group GM1, the thirdlens group G3 corresponds to the M2 lens group GM2, and the fourth lensgroup G4 corresponds to the RN lens group GRN.

The first lens group G1 consists of, in order from the object: apositive convexo-planar lens L11 having a convex surface facing theobject; and a positive cemented lens consisting of a negative meniscuslens L12 having a convex surface facing the object, and a positivemeniscus lens L13 having a convex surface facing the object.

The second lens group G2 consists of, in order from the object: anegative meniscus lens L21 having a convex surface facing the object; apositive biconvex lens L22; a negative biconcave lens L23; and anegative meniscus lens L24 having a concave surface facing the object.

The third lens group G3 consists of, in order from the object: apositive cemented lens consisting of a negative meniscus lens L31 havinga convex surface facing the object, and a positive biconvex lens L32; apositive cemented lens consisting of a positive biconvex lens L33, and anegative biconcave lens L34; an aperture stop S; a negative cementedlens consisting of a negative meniscus lens L35 having a convex surfacefacing the object, and a positive biconvex lens L36; and a positivebiconvex lens L37.

The fourth lens group G4 consists of, in order from the object: apositive meniscus lens L41 having a concave surface facing the object;and a negative biconcave lens L42.

The fifth lens group G5 consists of, in order from the object: anegative meniscus lens L51 having a concave surface facing the object; apositive biconvex lens L52; and a positive meniscus lens L53 having aconvex surface facing the object.

In the optical system according to this example, focusing from a longdistant object to a short distant object is performed by moving thefourth lens group G4 in the image surface direction. The imagingposition displacement due to a camera shake or the like is corrected bymoving the positive cemented lens that consists of the negative meniscuslens L31 having the convex surface facing the object and the positivebiconvex lens L32, in a direction orthogonal to the optical axis. Thatis, the lenses L31 and L32 constitute the vibration-proof lens group,and correspond to the A lens group of the present invention and thisembodiment.

Note that to correct a rotational blur with an angle θ at a lens havingthe focal length f of the entire system and a vibration proofcoefficient K (the ratio of the amount of image movement on the imageforming surface to the amount of movement of the movable lens group uponblur correction), the movable lens group for blur correction is moved ina direction orthogonal to the optical axis by (f·tan θ)/K. At thewide-angle end in the fourth example, the vibration proof coefficient is1.65, and the focal length is 72.1 mm. Accordingly, the amount ofmovement of the vibration-proof lens group to correct a rotational blurby 0.30° is 0.23 mm. In the telephoto end state in the fourth example,the vibration proof coefficient is 2.10, and the focal length is 292.0mm. Accordingly, the amount of movement of the vibration-proof lensgroup to correct a rotational blur by 0.20° is 0.49 mm.

The following Table 5 lists the values of data on the optical systemaccording to this example.

TABLE 5 Fifth Example [Lens data] Surface No. R D nd νd Object surface ∞1 109.5099 4.600 1.48749 70.32 2 ∞ 0.200 3 101.8486 1.800 1.62004 36.404 49.8873 7.200 1.49700 81.61 5 403.0130 Variable 6 166.1577 1.7001.69680 55.52 7 31.1882 3.953 8 32.0256 5.500 1.78472 25.64 9 −139.58161.553 10 −767.2482 1.300 1.77250 49.62 11 33.9202 4.300 12 −32.83511.200 1.85026 32.35 13 −256.2484 Variable 14 69.5902 1.200 1.80100 34.9215 29.9877 5.900 1.64000 60.19 16 −70.0411 1.500 17 36.2271 6.0001.48749 70.32 18 −39.9358 1.300 1.80610 40.97 19 820.8027 2.700 20 ∞14.092  (Stop S) 21 427.1813 1.200 1.83400 37.18 22 31.7606 4.8001.51680 63.88 23 −89.4727 0.200 24 73.5865 2.800 1.80100 34.92 25−110.0493 Variable 26 −83.7398 2.200 1.80518 25.45 27 −42.9999 6.500 28−36.8594 1.000 1.77250 49.62 29 73.0622 Variable 30 −26.0662 1.4001.62004 36.4  31 −40.4068 0.200 32 143.0444 3.035 1.67003 47.14 33−220.8402 0.200 34 100.4330 2.145 1.79002 47.32 35 170.3325 BF Imagesurface ∞ [Various data] Zooming ratio 4.05 W M T f 72.1 100.0 292.0 FNO4.48 4.85 5.87 2ω 33.94 24.44 8.42 Ymax 21.60 21.60 21.60 TL 190.21205.27 245.82 BF 39.12 46.37 67.13 [Variable distance data] W M T W M TShort Short Short Infinity Infinity Infinity distance distance distanced5 5.892 20.953 61.502 5.892 20.953 61.502 d13 30.000 22.752 2.00030.000 22.752 2.000 d25 2.212 3.707 3.900 2.864 4.521 5.606 d29 21.30619.811 19.618 20.654 18.997 17.912 [Lens group data] Group Startingsurface f G1 1 145.022 G2 6 −29.562 G3 14 38.233 G4 26 −48.257 G5 30318.066 [Conditional expression corresponding value] (1) fvr/fTM2 =1.738 (2) nvrN/nvrP = 1.098 (3) νvrN/νvrP = 0.580 (4) (−fTM1)/f1 = 0.204(5) fTM2/f1 = 0.264 (6) (−fN)/fP = 0.947 (7) f1/fw = 2.011 (8)f1/(−fTM1) = 4.906 (9) f1/fTM2 = 3.793

FIGS. 22A and 22B are graphs showing various aberrations of the zoomoptical system having a vibration-proof function according to the fifthexample upon focusing on infinity in the wide-angle end state, andgraphs showing meridional lateral aberrations when blur correction isapplied to a rotational blur by 0.30°, respectively. FIG. 23 is graphsshowing various aberrations of the zoom optical system having thevibration-proof function according to the fifth example upon focusing oninfinity in the intermediate focal length state. FIGS. 24A and 24B aregraphs showing various aberrations of the zoom optical system having avibration-proof function according to the fifth example upon focusing oninfinity in the telephoto end state, and graphs showing meridionallateral aberrations when blur correction is applied to a rotational blurby 0.20°, respectively. FIGS. 25A, 25B and 25C are graphs showingvarious aberrations of the zoom optical system according to the fifthexample upon focusing on a short distant object in the wide-angle endstate, the intermediate focal length state, and the telephoto end state,respectively.

The graphs showing various aberrations show that the zoom optical systemaccording to this example favorably corrects the various aberrations andhas excellent image forming performances from the wide-angle end stateto the telephoto end state, and further has excellent image formingperformances also upon focusing on a short distant object.

According to each of the examples described above, reduction in size andweight of the focusing lens group can achieve high-speed AF and silenceduring AF without increasing the size of the lens barrel, and the zoomoptical system can be achieved that favorably suppresses variation ofaberrations upon zooming from the wide-angle end state to the telephotoend state, and variation of aberrations upon focusing from an infinitedistant object to a short distant object.

Here, each of the examples described above represents a specific exampleof the invention of the present application. The invention of thepresent application is not limited thereto.

Note that the following details can be appropriately adopted in a rangewithout impairing the optical performance of the zoom optical system ofthe present application.

The five-group configurations and the six-group configurations have beendescribed as the numeric examples of the zoom optical systems of thepresent application. However, the present application is not limitedthereto. Zoom optical systems having other group configurations (forexample, seven-group ones and the like) can also be configured.Specifically, a zoom optical system having a configuration where a lensor a lens group is added to the zoom optical system of the presentapplication at a position nearest to the object or to the image surfacemay be configured. Note that the lens group indicates a portion that hasat least one lens and is separated by air distances varying uponzooming.

The lens surfaces of the lenses constituting the zoom optical system ofthe present application may be spherical surfaces, plane surfaces, oraspherical surfaces. A case where the lens surface is a sphericalsurface or a plane surface facilitates lens processing and assemblyadjustment, and can prevent the optical performance from being reducedowing to the errors in lens processing or assembly adjustment.Consequently, the case is preferable. It is also preferable becausereduction in depiction performance is small even when the image surfacedeviates. In a case where the lens surface is an aspherical surface, thesurface may be an aspherical surface made by a grinding process, a glassmold aspherical surface made by forming glass into an aspherical shapewith a mold, or a composite type aspherical surface made by formingresin provided on the glass surface into an aspherical shape. The lenssurface may be a diffractive surface. The lens may be a gradient indexlens (GRIN lens) or a plastic lens.

An antireflection film having a high transmissivity over a widewavelength range may be applied to the lens surfaces of the lensesconstituting the zoom optical system of the present application. Thisreduces flares and ghosts, and can achieve a high optical performancehaving a high contrast.

According to the configurations described above, this camera 1 mountedwith the zoom optical system according to the first example as theimaging lens 2 can achieve high-speed AF and silence during AF withoutincreasing the size of the lens barrel, by reducing the size and weightof the focusing lens group, can favorably suppresses variation ofaberrations upon zooming from the wide-angle end state to the telephotoend state, and variation of aberrations upon focusing from an infinitedistant object to a short distant object, and can achieve a favorableoptical performance. Note that possible configurations of camerasmounted with the zoom optical systems according to the second to seventhexamples described above as the imaging lens 2 can also exert theadvantageous effects analogous to those of the camera 1 described above.

EXPLANATION OF NUMERALS AND CHARACTERS G1 First lens group G2 Secondlens group G3 Third lens group G4 Fourth lens group G5 Fifth lens groupGFS Front lens group GM1 M1 lens group GM2 M2 lens group GRN RN lensgroup I Image surface S Aperture stop

1-18. (canceled)
 19. A zoom optical system comprising, in order from anobject: a front lens group having positive refractive power; an M1 lensgroup having negative refractive power; an M2 lens group having positiverefractive power; and an RN lens group having negative refractive power,wherein upon zooming, a distance between the front lens group and the M1lens group changes, a distance between the M1 lens group and the M2 lensgroup changes, and a distance between the M2 lens group and the RN lensgroup changes, upon zooming, a lens group nearest to the object in theM1 lens group is fixed with respect to an image surface, upon zoomingfrom a wide-angle end state to a telephoto end state, the front lensgroup moves toward the object, upon focusing from an infinite distantobject to a short distant object, the RN lens group moves, and thefollowing conditional expressions are satisfied,0.15<(−fTM1)/f1<0.350.20<fTM2/f1<0.341.90<f1/fw<3.50 where fTM1: a focal length of the front lens group in atelephoto end state, fTM2: a focal length of the M2 lens group in atelephoto end state, f1: a focal length of the front lens group, and fw:a focal length of the zoom optical system in a wide-angle end state. 20.The zoom optical system according to claim 19, wherein the M2 lens groupcomprises an A lens group, and a following conditional expression issatisfied,1.10<fvr/fTM2<2.00 where fvr: a focal length of the A lens group. 21.The zoom optical system according to claim 20, wherein the A lens groupcomprising of, a lens component of a lens having a positive refractivelens and a lens of a negative refractive lens, and a followingconditional expression is satisfied,1.00<nvrN/nvrP<1.25 where nvrN: a refractive index of the lens havingthe negative refractive power in the A lens group, and nvrP: arefractive index of the lens having the positive refractive power in theA lens group.
 22. The zoom optical system according to claim 20, whereinthe A lens group comprising of, a lens component of a lens having apositive refractive lens and a lens of a negative refractive lens, and afollowing conditional expression is satisfied,0.30<vvrN/vvrP<0.90 where vvrN: an Abbe number of the lens having thenegative refractive power in the A lens group, and vvrP: an Abbe numberof the lens having the positive refractive power in the A lens group.23. The zoom optical system according to claim 19, wherein the frontlens group consists of, in order from the object, a lens having apositive refractive power, a lens having a negative refractive power,and a lens having a positive refractive power.
 24. The zoom opticalsystem according to claim 19, wherein further comprising, in order fromthe object, a lens having a negative refractive power and a lens havinga positive refractive power, which are provided adjacent to the RN lensgroup on an image side.
 25. The zoom optical system according to claim24, wherein a following conditional expression is satisfied,0.70<(−fN)/fP<2.00 where fN: a focal length of a lens that has astrongest negative refractive power among lenses disposed to the imageside of the RN lens group, and fP: a focal length of a lens that has astrongest positive refractive power among lenses disposed to the imageside of the RN lens group.
 26. An optical apparatus comprising the zoomoptical according to claim
 19. 27. A method for manufacturing a zoomoptical system, which comprises in order from an object, a front lensgroup having positive refractive power, an M1 lens group having negativerefractive power, an M2 lens group having positive refractive power, andan RN lens group having negative refractive power, comprising a step forarranging the lens groups in a lens barrel so that; upon zooming, adistance between the front lens group and the M1 lens group changes, adistance between the M1 lens group and the M2 lens group changes, and adistance between the M2 lens group and the RN lens group changes, uponzooming, a lens group nearest to the object in the M1 lens group isfixed with respect to an image surface, upon zooming from a wide-angleend state to a telephoto end state, the front lens group moves towardthe object, upon focusing from an infinite distant object to a shortdistant object, the RN lens group moves, and the following conditionalexpressions are satisfied,0.15<(−fTM1)/f1<0.350.20<fTM2/f1<0.341.90<f1/fw<3.50 where fTM1: a focal length of the front lens group in atelephoto end state, fTM2: a focal length of the M2 lens group in atelephoto end state, f1: a focal length of the front lens group, and fw:a focal length of the zoom optical system in a wide-angle end state.